Enantiomer Separations by Normal HPLC Systems with Permethylated β-Cyclodextrin Dynamically Coated on Silica Solid Supports

Expanding cyclodextrin use in normal phase and super/subcritical fluid chromatographic modes for the chiral separation of 1,4-dihydropyridines

Cyclodextrin-based stationary phases are important chiral selectors in liquid chromatography. These chiral selectors are most commonly used in the reversed-phase mode because native cyclodextrin assumes a torus conformation with a hydrophobic cavity, facilitating inclusion complexation in aqueous environments. However, the value of native and aliphatic-derivatized cyclodextrins in other modes, such as the normal phase liquid chromatography (NPLC) or super/subcritical fluid chromatography (SFC), remains unexplored. In this work, we report chiral separations of pharmaceutically relevant compounds with the 1,4-dihydropyridine (DHP) scaffold on a 2-hydroxypropyl-β-cyclodextrin (CD-RSP) stationary phase in NPLC and SFC modes. Although CD-RSP is conventionally considered only effective in the reversed-phase mode, we show that these compounds tend to separate better in other modes. This is particularly apparent for analytes with hydrogen-bonding moieties. We propose that the separation mechanism primarily depends on external adsorption rather than inclusion complexation. The negligible impact of a complexation-competitive additive on retention in non-aqueous modes further supports this claim. Additionally, van Deemter analysis demonstrated the efficiency and environmental benefit of using this stationary phase in the SFC mode, further highlighting the promise of aliphatic derivatized cyclodextrin stationary phases for greener separations.

Evaluation of the stability and selectivity for various adjustable stationary phases using zirconium oxide supports in high-performance liquid chromatography

The selectivity and retention properties of a zirconia stationary phase were reversibly altered using various ligands containing Lewis base functional groups. A simple loading procedure allowed a variety of ligands to be attached to the zirconia surface via Lewis interactions. The resulting stationary phases were shown to be stable and produced different selectivity and retention properties from the native zirconia material. The metal oxide adsorbent was converted to a diol-type stationary phase using glucose-6-phosphate for use under normal-phase conditions. Reversed-phase supports were produced by loading either octyl- or octadecylphosphonic acid onto the native zirconia support. The properties of these new phases were then compared to commercially available bonded silica analogs. Ligands bound to the surface in this manner were effectively removed and the native zirconia was regenerated using a dilute base wash procedure.

Chiral supercritical fluid chromatography on porous graphitic carbon using commercial dimethyl beta-cyclodextrins as mobile phase additive

Using dimethylated-beta-cyclodextrin mixtures (MeCD) as chiral selectors in CO2-polar modifier mobile phase and porous graphitic carbon as solid-phase, chiral supercritical (or subcritical) fluid chromatography was performed. The adsorbed quantity of MeCD onto the porous graphitic carbon (Hypercarb) was measured for various chiral selector concentrations using the breakthrough method with evaporative light scattering detector. The effects of MeCD concentration in the mobile phase, the nature of the polar modifier, the outlet pressure, the column temperature and the nature of the commercial MeCD mixture on the retention and the enantioselectivities were studied. For a given solute, the enantioselectivity is greatly dependent on the commercial MeCD mixture used. The retention mechanism was also studied. From the data, we find that the dominant mechanism for the chiral discrimination is the diastereoisomeric complexation in the mobile phase.

Direct enantiomeric separations by high performance liquid chromatography using cyclodextrins

Due to their identical chemical and physical properties, the separation of enantiomers has been considered one of the most difficult challenges in chemistry from both an analytical or a preparative viewpoint. With the development and commercialization of many new or improved chiral stationary phases and chiral additives, interest in enantiomeric separation by HPLC has grown tremendously in the last two decades. Cyclodextrins and modified cyclodextrins are widely used chiral selectors. They are used as either the chiral stationary phases, as chiral mobile phase additives, or as chiral counter-ions. This review describes the historical development of derivatized and underivatized cyclodextrins in HPLC and their various applications.